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Energy Landscapes: Clusters, Glasses, and Biomolecules
Objective: to exploit stationary points (minima and transition states) of the
PES as a computational framework (J. Phys. Chem. B, 110, 20765, 2006):
• Basin-hopping for global optimisation (J. Phys. Chem. A, 101, 5111 1997)
• Superposition approach for thermodynamics (Chem. Phys. Lett., 466, 105, 2008)
• Discrete path sampling for global kinetics (Mol. Phys., 100, 3285, 2002)
Free energy surfaces for alanine dipeptide (CHARMM22/vacuum) from su-
perposition, replica exchange, and reaction path Hamiltonian superposition:
The Reaction Path Hamiltonian Superposition Approach
The total partition function as a function of order parameter a is constructed
as a superposition of contributions from local minima, Zi(a, T ), and config-
urations taken from the pathways that connect them, Z†r(a, T ):
Zi(a, T ) =
(
kT
hνi
)κexp (−Vi/kT )√
2πkTAi
exp
[
−(a − ai)2
2kTAi
]
,
Z†r(a, T ) =
(
kT
h
)κ δr exp(
−V †r /kT
)
(
ν†r
)κ−1
2πkT√
A†r
exp
[
(
a − a†r)2
2kTA†r
]
,
where νi is the geometric mean of the normal mode frequencies, νi,γ, Vi
and ai are the potential energy and order parameter for minimum i, δr is a
displacement, † labels transition states, and
Ai =
κ∑
γ=1
[
∂a(qi)
∂qi,γ
∣
∣
∣
∣
qi=0
1
2πνi,γ
]2
.
The method can be extended for projections onto additional order parameters.
The ‘filling in’ problem for barrier regions in low-dimensional projections due
to overlapping distributions can be avoided using disconnectivity graphs.
The effect of regrouping for a barrier threshold of 3 kcal/mol is shown below
for AMBER(ff03)/GBOCB (left) and compared with the CHARMM22/vacuum
surface (right). Free energy of group J : FJ(T ) = −kT ln∑
j∈J Zj(T ) with
F†LJ(T ) = −kT ln
∑
l←j
Z†lj(T ), and kLJ(T ) =
kT
he−[F
†LJ
(T )−FJ (T )]/kT .
Basin-Hopping Global Optimisation (J. Phys. Chem. A, 101, 5111, 1997)
(NaCl)18Na+HYPA/FBP11
38 75 76
77
98
102 103 104
Non-icosahedral Lennard-Jones Clusters Binary LJ unit cell
corronene10 (H2O)20 H3O+(H2O)20 Eigen H3O
+(H2O)20 Zundel
Stockmayer
Thomson problem
Structure Prediction for Human Influenza Virus Hemagglutinin
Influenza virus is a variable pathogen, causing problems for vaccination.
Antigenic shift of the hemagglutinin glycoprotein, which binds sialic acid at
the cell surface, produces pandemics. Antigenic drift gives rise to epidemics.
Crystal structure is known for HK68 (H3N2). The single TY155 mutation,
from threonine to tyrosine led to a cluster transition from HK68.
Angle-Axis Coordinates for Rigid Bodies (PCCP, 11, 1970, 2009)
Rodrigues’ formula for the rotation matrix R corresponding to a rotation of
magnitude θ = (p2
1+ p2
2+ p2
3)1/2 around the axis defined by p is
R = I + (1 − cos θ)pp + sin θ p,
where I is the identity matrix, and p is the skew-symmetric matrix
p =1
θ
0 −p3 p2
p3 0 −p1
−p2 p1 0
.
The product of p and any vector v returns the cross product: pv = p × v.
All terms involving rigid-body angle-axis coordinates can be obtained by the
action of the rotation matrix and its derivatives, whose forms are programmed
in system-independent subroutines.
The angle-axis representation is free of singularities and constraints.
1st derivatives: Rk ≡∂R
∂pk
=pk sin θ
θep2
+ (1 − cos θ)(epkep + epepk) +pk cos θ
θep + sin θ epk, with ep1 =
1
θ3
0
B
@
0 p1p3 −p1p2
−p1p3 0 p2
1− θ2
p1p2 θ2 − p2
10
1
C
A
2nd derivatives : Rkk ≡∂2R
∂p2
k
=2pk sin θ
θ(epkep + epepk) +
p2
k cos θ
θ2−
p2
k sin θ
θ3+
sin θ
θ
!
ep2
+ (1 − cos θ)(2ep2
k + epkkep + epepkk) + (−p2
k sin θ
θ2−
p2
k cos θ
θ3+
cos θ
θ)ep +
2pk cos θ
θepk + sin θ epkk,
and Rkl ≡∂2R
∂pkpl
=pk sin θ
θ(eplep + epepl) + (
pkpl cos θ
θ2−
pkpl sin θ
θ3)ep
2+
pl sin θ
θ(epkep + epepk)
+ (1 − cos θ)(epklep + epkepl + eplepk + epepkl) − (pkpl sin θ
θ2+
pkpl cos θ
θ3)ep +
pk cos θ
θepl +
pl cos θ
θepk + sin θ epkl.
Denote positions in the body-fixed frame by superscript 0. For rigid bodies I and J with sites i and j defining site-site isotropic potentials UIJij the potential energy is
U =X
I
X
J<I
X
i∈I
X
j∈J
fij(rij), where rij = |rij | = |ri − rj | and fij ≡ UIJij so that
∂U
∂ζ=X
J 6=I
X
i∈I
X
j∈J
f′ij(rij)
∂rij
∂ζ, where f
′ij =
dfij(rij)
drij
,∂rij
∂rI= rij ,
∂rij
∂pIk
= rij ·∂rij
∂pIk
= rij ·(RIkr
0
i ), rij = rI+R
Ir0
i −rJ−R
Jr0
j .
∂2UIJij
∂rIk
∂rJl
= f2(rij)rij,krij,lǫIJ + f1(rij)δklǫIJ ,
∂2UIJij
∂pIk
∂pJl
= f2(rij)(rij · RIkr
0
i )(rij · RIl r
0
i )δIJ − f2(rij)(rij · RIkr
0
i )(rij · RJl r
0
j )(1 − δIJ ) + f1(rij)(RIkr
0
i ) · (RIl r
0
i )δIJ
−f1(rij)(RIkr
0
i ) · (RJl r
0
j )(1 − δIJ ) + f1(rij)(rij · RIklr
0
i )δIJ ,
∂2UIJij
∂rIk
∂pJl
= f2(rij)(rij · RIl r
0
i )rij,kδIJ − f2(rij)(rij · RJl r
0
j )rij,k(1 − δIJ ) + f1(rij)[RIkr
0
i ]lδIJ − f1(rij)[RJl r
0
j ]l(1 − δIJ ).
where f1(rij) = f ′ij(rij)/rij , f2(rij) = f ′
1(rij)/rij , ǫIJ = 1 for I = J and ǫIJ = −1 for I 6= J , and δIJ is the Kronecker delta.
Self-Assembly of Icosahedral Shells (PCCP, 11, 2098-2104, 2009)
R1 R2Rax
r
Palm tree disconnectivity graphs with Ih global minima are found for
T = 1 and T = 3 shells constructed from pentagonal and hexagonal pyramids.
Landscapes of this form are associated with good structure-seekers.
24 Pentagonal Pyramids
For the same parameters two T = 1 icosahedra are similar in energy to a
single shell based on a snub cube. Polyoma virus capsid protein VP1 forms a
left-handed snub cube from alkaline solution in the absence of the genome.
Clusters of Ellipsoids (Phys. Rev. Lett., 99, 086106, 2007)
−286,6
−286,8
−287,0
−287,2
−286,4
−286,2
−286,0
Clusters of discoids bound by the Paramonov-Yaliraki potential exhibit helical
global minima when the dimer has a shifted stacked configuration.
The corresponding energy landscapes generally have single funnel topologies
for both single and multiple strand helices.
Modelling Mesos opi Stru tures
top
side
Mixing building blocks that favour shells and tubes produces structures with
distinct head and tail regions (left): the Frankenphage.Particles with a Lennard-Jones site buried in the ellipsoid assemble into a
spiral structure (right) with parameters similar to tobacco mosaic virus.
Interfaces to Electronic Structure Packages
Transition states: single-ended searches use hybrid eigenvector-following
(Phys. Rev. B, 59, 3969, 1999; Chem. Phys. Lett., 341, 185, 2001), double-ended searches
use the doubly-nudged elastic band approach (J. Chem. Phys., 120, 2082, 2004).
These methods can be combined with electronic structure calculations.
• Defect migration in crystalline silicon (Chem. Phys. Lett., 341, 185, 2001).
• Hydrocarbon dissociation on Pt{110} (1 × 2) (J. Chem. Phys., 126, 044710,
2007). For ethane, low barriers (0.3 to 0.4 eV) are found for initial formation
of ethene and ethylidene, medium barriers (0.7 to 1.1 eV) are found for
dehydrogenation of C2H4 fragments to vinylidene and ethyne, and high
barriers in excess of 1.45 eV arise for further dehydrogenation.
• Ammonia synthesis and dissociation on Fe{211}: the Haber-Bosch process.
We predict that atomic nitrogen can be hydrogenated above around 340 K,
with ammonia being evolved at temperatures above 570-670 K.
Discrete Path Sampling (Mol. Phys., 100, 3285, 2002).
A AB B
I
aa bbi
no intervening minima pi(t) = 0pa(t)pa′(t)
=peq
a
peqa′
pb(t)pb′(t)
=p
eqb
peqb′
Phenomenological A ↔ B rate constants can be formulated as sums over
discrete paths, defined as sequences of local minima and the transition states
that link them, weighted by equilibrium occupation probabilities, peqb :
kSSAB =
1
peqB
∑
a←b
Pai1Pi1i2 · · ·Pin−1inPinbτ−1b p
eqb =
1
peqB
∑
b∈B
CAb p
eqb
τb
,
where Pαβ is a branching probability and CAb is the committor probability that
the system will visit an A minimum before it returns to the B region.
Discrete path sampling is a framework for growing databases of stationary
points that are relevant to global kinetics (Int. Rev. Phys. Chem., 25, 237, 2006).
A hierarchy of expressions can be obtained for the rate constants:
kSSAB =
1
peqB
∑
b∈B
CA
bp
eqb
τb
, kNSSAB =
1
peqB
∑
b∈B
CA
bp
eqb
tb, kAB =
1
peqB
∑
b∈B
peqb
TAb
.
τb, tb and TAb are the mean waiting times for a transition from b to an adjacent
minimum, to any member of A ∪ B, and to the A set, with τb ≤ tb ≤ TAb.
kAB
is formally exact within a Markov assumption for transitions between
the states, which can be regrouped. Additional approximations come from
incomplete sampling, and the densities of states and transition state theory
used to describe the local thermodynamics and kinetics.
Calculating kAB
using diagonalisation, successive overrelaxation (SOR), or
kinetic Monte Carlo (KMC) can become unfeasible for large databases.
Kinetic Analysis by Graph Transformation (JCP, 124, 234110, 2006)
The graph transformation procedure is non-stochastic and non-iterative. Min-
ima, x, are progressively removed, while the branching probabilities and wait-
ing times in adjacent minima, β ∈ Γ, are renormalised:
P ′
γβ = Pγβ + PγxPxβ
∞∑
m=0
Pmxx = Pγβ +
PγxPxβ
1 − Pxx
, τ ′
β = τβ +Pxβτx
1 − Pxx
.
Each transformation conserves the MFPT from every reactant state to the
set of product states with an execution time independent of temperature:
kT/K ∆Fbarrier Nmin Nts NGT/s SOR/s KMC/s
298 5.0 272 287 8 13 85,138
298 4.5 2,344 2,462 8 217,830
1007 - 40,000 58,410 35 281 1,020,540
1690 - 40,000 58,410 39 122,242
Folding of Beta3s
−620
−630
−640
−650
−660
−670
−680
−460
−480
−500
−520
−5400 500 1000 1500 2000
s/A
Etot
Enb
−686
−682
−678
−674
−670
−666
−662
−658
−654
−650
−646
−642
−638
−634
−630
−626
−622
V(k
cal/
mol)
Beta3s is a designed 20-residue peptide with a three-stranded antiparallel
β-sheet. Folding with CHARMM19/EEF1 involves early formation of the
C-terminal hairpin followed by docking of the N-terminal strand.
Mean first passage time is 300 ns at 298 K, consistent with other calculations
and the experimental upper bound of 4000 ns (J. Phys. Chem. B, 112, 8760, 2008).
Aggregation of the GNNQQNY Peptide
0
2
4
6
8
≥ 10
5.5 6 6.5 7 7.5 8 8.5 0
2
4
6
8
10
CD
IA
CM
OPIP
Rg [A]
RM
SD
[A]
IAOP
CD IP
CM0
−5
−10
−15
−20
−25
−30
free
ener
gy[k
calm
ol−
1]
GNNQQNY is a polar heptapeptide from
the N-terminal prion-determining region
of the 685 residue yeast prion protein Sup35. Dimer free energy minima are
in-register parallel, IP, off-register parallel, OP, and antiparallel, IA, sheets.
Dimer formation rates are estimated as milliseconds to seconds. Time scale
for interconversion between dimers ranges from hours to days at 298 K.
Amyloid Formation in ccβ (J. Phys. Chem. B, 112, 9998, 2008)
The designed peptide ccβ adopts a trimeric coiled-coil structure, but trans-
forms to give amyloid fibrils on raising the temperature to 310 K.
CHARMM19/EEF1 free energy surface includes the β-sheet structure de-
duced from experiment. Paths between the α-helical trimer and β-sheet
structure involve over 1000 transition states.
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